Ultrasonic consumption meter with locking mechanism

ABSTRACT

An ultrasonic consumption meter includes two ultrasonic transducers for emitting and receiving ultrasonic waves, a flow channel, an electronic circuit for operating the meter, and a housing for the ultrasonic transducers and the electronic circuit. The housing is locked in position relative to the flow channel by a locking mechanism, and the flow channel has two holes for allowing the housing to get into contact with a media flowing in the flow channel.

FIELD OF THE INVENTION

This invention concerns an ultrasonic consumption meter for meteringfluid substances such as water or gas, especially a meter exposed tocondensing conditions or other harmful environments.

BACKGROUND OF THE INVENTION

Electronic consumption meters are delicate equipment that will sufferwhen placed in harmful environments, unless sensitive parts are wellprotected. The main cause of dysfunction is due to corrosion of theelectronic circuit or the components.

As an example, an electronic meter for cold water is exposed tocondensing water from the surrounding air, due to the temperaturedifference between the water in the meter and the potentially humid air.Other potentially harmful components in the environment could beaggressive gases or dust. An electronic water meter is also in risk ofbeing dysfunctional, if water from the flow channel penetrates thebarrier between the flow channel and the electronics.

Several known ways exist for protecting sensitive electronics in anultrasonic consumption meter, which will be discussed below

-   -   Hermetically sealed box for the electronics with sealed        electrical connections between the transducers and the        electronics. This is an effective solution, but unfortunately it        is very costly, as sealed electrical connections are complex to        manufacture.    -   Potted electronics with or without potted transducers (an        example is shown in EP1983311). This I not a very effective        solution for long-term exposure of moisture or water, as known        materials for potting of electronics has a relatively high        degree of vapor penetration. A water meter is typically used for        many years, and in some cases it will even be submerged in water        for very long periods. Thus the risk of damage to the meter is        high in these conditions.    -   Multilayer protection of electronics and transducers (an example        is shown in EP2083251). This can be effective in some        applications, but it is complex and expensive.

Thus it is an objective to provide a cost-effective ultrasonic basedconsumption meter in which the sensitive parts are effectively protectedagainst water and other harmful substances. Other parameters to takeinto consideration are the strength and durability of the meter, inparticular the flow channel and the connections to connecting tubes suchas treads.

SUMMARY OF THE INVENTION

It is the object of this invention to provide a low cost, durable, andlong-lived ultrasonic consumption meter protected against moisture,water and other substances coming from the surroundings and from theinside of the flow channel.

The ultrasonic consumption meter comprises:

-   -   a flow channel for the media to be measured;    -   ultrasonic transducers for emitting and receiving ultrasound;    -   electronic circuit for operating the meter;    -   a housing for the transducers and electronic circuit;    -   and;    -   a locking mechanism that locks the housing in position relative        to the flow channel.

The flow channel directs the media to be measured between an inlet andan outlet. The flow channel has to be able to withstand the pressure ofthe media inside, and it has to be able to withstand forces applied toit from the outside. For a water meter, this is most preferably obtainedif the flow channel is made of a metal such as brass or stainless steel,for a gas meter the strength requirements can be satisfied by polymers.In a beneficial embodiment, other features are placed in the flowchannel between the inlet and the outlet, such as reflectors forredirecting ultrasonic waves, flow disturbance correctors, and dimensionchanges for optimization of the flow directions and velocities insidethe flow channel. Such features can be made of several differentmaterials, such as polymers, glass filled polymers or metal.

The flow channel directs the media to be measured between an inlet andan outlet. The flow channel has to be able to withstand the pressure ofthe media inside, and it has to be able to withstand forces applied toit from the outside. For a water meter, this is most preferably obtainedif the flow channel is made of a metal such as brass or stainless steel,for a gas meter the strength requirements can be satisfied by polymers.In a beneficial embodiment, other features are placed in the flowchannel between the inlet and the outlet, such as reflectors forredirecting ultrasonic waves, flow disturbance correctors, and dimensionchanges for optimization of the flow directions and velocities insidethe flow channel. Such features can be made of several differentmaterials, such as polymers, glass filled polymers or metal.

The housing comprises at least two parts: a cup and a lid, with ahermetical seal between the two.

The cup is most preferably made of a low-diffusion, high strengthpolymeric material, such as High Density-polymers like PPS(Polyphenylene Sulphide) or PSU (Polyether Sulfone). Although thesematerials are not completely impenetrable for water, the penetrationrate is very small, and many years of safe operation can be expected.Further increase in material strength is achieved by a mixing thepolymer with fibers, such as glass fibers or mineral fibers. 40% glassfibers are preferred, as this makes a comfortable compromise betweenproduceability, cost, and strength. As an alternative the cup can bemanufactured out of metal, but this is considered less optimal, due tocost and design constraints.

Some optional features as mentioned in the description of the flowchannel can be mounted on the cup, such as reflectors or flowcorrectors.

The lid is also most preferably made of a low-diffusion material such asa High Density-polymer. Unfortunately most of these are opaque orlight-tight, so if a display is a part of the electronic circuit, itcannot be seen. Thus in such cases, glass or special polymers like COC(CYCLIC OLEFIN COPOLYMER) are favorably used for the lid. Thesematerials exhibits transparency as well as a low diffusion rate of watervapor.

The hermetical seal between the lid and the cup can be one or moreo-rings, a fluid rubber material, a welding seam or glue.

The lid is preferably held in place by a locking ring. The locking holdsthe cup and the lid together, and it can be secured by a legal seal, sothat opening of the meter leaves visible traces.

Depending on the materials used and the effectiveness of the seal, asmall amount of water vapor might penetrate the housing during the yearsof use. In this case further protection of the electronics fromcorrosion is obtained by placing a desiccant inside the housing.Examples of desiccants are silica gel, calcium sulfate, calciumchloride, some types of clay, and molecular sieves.

Especially advantageous is a housing impenetrated by electrical wires,as this lowers the risk of imperfections and leakage of water vapor andother hazardous substances into the housing.

The ultrasonic transducers are typically made of a piezo electricalmaterial, typically of the Lead Zirconate Titanate (PZT) type. Thetransducers emit ultrasonic waves when a voltage differential isasserted to them, and they produce an electrical charge when anultrasonic pressure wave is asserted to them. At certain frequencies,depending on the material parameters and the mechanical shape of thetransducers, the transformation between the energy forms voltage,ultrasonic pressure waves, and electrical charge is most efficient. Suchfrequencies are called resonance frequencies. When the piezo material isdirectly acoustically coupled to other materials, this will affect theresonance frequencies and the level of transformation between thedifferent forms of energy. An advantageous position of the piezoelectric material is inside the housing, so that electrical connectionspenetrating the housing are avoided. This means, that the piezo electricmaterial is pressed against the housing at appropriate places, with anacoustical coupling material in between. The acoustical couplingmaterial assures that acoustical energy is transported with littleenergy loss between the piezo electric material and the housing, and itcan preferably be of the following types: silicon oil, silicon gel,glycol, glue, conducting glue, or oil. Appropriate force on the piezoelectric material towards the housing is most preferably achieved bysprings on the backside of the piezo electric material. Especiallyadvantageous are metallic springs, with the additional function thatthey can be used for electrical connections between the piezo electricmaterial and the electronic circuit.

The electronic circuit controls the emission and reception of ultrasonicsignals, and converts the received signals to one or more usable values,depending on the flow in the flow channel. The values are shown on adisplay inside the housing, or it is transmitted to the outside of thehousing by radio waves, magnetic pulses, electrostatic pulses, lightpulses, or wires, or a combination of the six alternatives. Wirelesstransmission of values is preferred, so that electrical connectionspenetrating the housing can be avoided.

The electronic circuit is connected to a power supply, most preferably abattery placed inside the housing. Other solutions for the power supplyare: a wired connection to an energy source outside the housing or anenergy harvesting circuit placed inside the housing collectingmechanical, electromagnetic, magnetic, electrostatic, thermal, orradioactive energy from the environment and converting it to electricalenergy. A harvesting circuit needs a power supply back-up system such asa rechargeable battery or a high capacity capacitor for periods withoutexternal energy sources.

The locking mechanism ensures that the housing does not move relative tothe flow channel. This is important, as the piezo electric material isplaced inside the housing, and thus movements between the housing andthe flow channel potentially affects the measurement results.

Further, preferably the flow channel will have holes, so that ultrasoundtransmitted from the piezo electric material through the housing willenter easily into the media streaming in the flow channel. These holesmust be sealed, so that the media will not flow outside the flowchannel, so the sealing is placed between the housing and the flowchannel. The locking mechanism ensures that this sealing has to absorbonly small or no movements between the flow channel and the housing.

A simple locking mechanism could be screws holding the two piecestogether, but a preferred solution is a locking mechanism with noscrews, as this is the optimal solution for automated production. Such alocking mechanism is proposed in this invention.

On the outside of the flow channel protrusions are made so that one ormore fixing pins locks the housing in position, when the fixing pins areinserted into matching holes in the cup, after this is correctly placedin position at the flow channel.

Alternatively, the holes in the cup can be incomplete, such as notcompletely surrounding the pins when they are inserted.

In the simplest form, the protrusions on the flow channel are positionedabove protrusions on the cup with an offset. This allows the protrusionson the two parts to pass each other in the assembly process, so that thecup can be mounted on the flow channel without any protrusions from thetwo parts touching each other. The locking process is thus operatinglike a zipper, the housing and the flow channel being zipped together bythe one or more locking pins.

It is preferred that the one or more locking pins are moved intoposition in a movement parallel to the flow channel as this allows alarger distribution area for the forces that arises on the housing, whenthe pressure in the flow channel rises.

An invisible locking mechanism can be obtained by hiding all the lockingprotrusions of one of the parts, by protrusions on the other part.

The one or more locking pins may advantageously be secured by a sealing,so that disassembly of the meter leaves a visible trace.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a drawing of a complete consumption meter

FIG. 2 illustrates an exploded view of the three parts involved in thelocking mechanism

FIG. 3 illustrates an exploded view of the complete meter

FIG. 4 illustrates a sliced view of the complete meter. The insert 10 ais fixed in its position, by the feature 10 b on the cup

FIG. 5a and FIG. 5b illustrate a detail of the locking mechanism, withfull holes in the cup as part of the locking mechanism

FIG. 5c and FIG. 5d illustrate a detail of the locking mechanism, withsimple protrusions on the cup as part of the locking mechanism

FIG. 6 illustrates a detail of an invisible locking mechanism

DETAILED DESCRIPTION OF THE INVENTION

Referring now to the drawings, the elements are numbered as follows:

A lid (1) is part of the housing. If a display or a front plate ispresent inside the housing, a transparent lid is advantageous. The lidis a part of the housing.

A front plate (2) with information about the consumption meter, isvisible through the lid. The information can be of the following kind,but is not limited to: meter number, approval number, meter type, vendorname, utility name, meter size, or machine readable information such asbarcodes or patterns.

An electronic circuit (3), comprising a Printed Circuit Board,electronic components, a power supply unit, such as a battery, and adisplay is part of the meter. In an advantageous embodiment, theinterfaces for communication, such as optical communication, radiocommunication, or wired communication are a part of the electroniccircuit. In addition to values derived from measurements, the displaycan optionally show information received via the communicationinterfaces. In an especially advantageous embodiment, a pressuresensitive device is included in the electronic circuit, so that thepressure in the hermetically sealed housing is supervised.

A locking ring (4) holds the lid and the cup together. The ring isdivided at one place on the perimeter, so that it can be fixed aroundthe lid and the cup. In a consumption meter used for billing it isadvantageous to secure the locking ring with a seal, so that it isimpossible to open the lid without breaking the seal or the lockingring. An advantageous means for sealing is a wire drawn through twoholes on the locking ring, one hole on each side of the division of thering. Alternatively a piece of marked adhesive tape that breaks when itis removed can be used as a seal. A polymeric material is mostadvantageous for the locking ring the material can be with or withoutreinforcing fibers.

A piezo electric material, transducers, (5) emit and receive ultrasoundsignals. A suitable material is PZT sintered and machined to size andthen polarized. In Doppler effect based consumption meters a singlepiece of piezo electric material suffices in most cases, for consumptionmeters based on the transit time principle, at least two pieces of piezoelectric material are needed.

A cup (6), is a part of the housing that holds the electronic circuitand the piezo electric material. In some embodiments it is beneficial todesign the cup large enough for a desiccant to be placed inside thehousing. The desiccant can be placed in a separate compartment with aseparate lid inside the cup, or it can be handled in a small bag whichis put inside the cup. The cup is attached to the flow channel with oneor more locking pins. The cup is most preferably made in a single pieceof fiber reinforced polymer. As the housing is hermetically sealed, itcan be difficult to press the lid into the cup in an environment withnormal air-pressure, as the air trapped inside the housing will apply anincreased pressure on the lid from the inside when the lid is closing.Thus it is beneficial to locally lower the pressure of the airsurrounding the housing during the assembly process, such as in an airtight assembly box. Alternatively a small hole on the side of the cupwill allow air to be pressed out during the assembly of the lid, andthen the hole can be plugged at a later stage. The plug can be of thesame material as the cup or another material, and it can be glued,welded or pressed to the cup, alternatively the plug is sealed with ano-ring or similar. For practical reasons, the diameter of the cup istypically less than 15 cm and larger than 3 cm. The height of the cup istypically less than 6 cm and larger than 1 cm.

A sealing means (7) can be located between the flow channel and thehousing. In the preferred embodiment this sealing means consists of oneor more o-rings. The o-rings prevent the media to be measured by themeter to escape from the flow channel. The o-ring has preferably amaterial diameter of 0.5 to 4 mm, and the hole typically has a diameterof 5 to 15 mm. The o-rings are made of rubber-like or thermoplasticmaterial.

One or more locking pins (8) fasten the housing to the flow channel. Thelocking pin is inserted parallel or perpendicular to the flow channelbetween protrusions in the cup and the flow channel. This way the twoparts are locked together. After insertion, the locking pin can besecured by sealing means that prevents extraction of the pin withoutleaving a visible trace on the seal or the housing or the flow channel.An advantageous sealing means is a wire drawn through a hole in thelocking pin. The seal securing the locking pin can be combined with theseals securing the locking ring.

A flow channel (9) directs the media to be metered from an inlet to anoutlet. In a preferred embodiment, the media is water, and the flowchannel is made of an extruded piece of brass that is cut to a suitablelength and then machined for the desired shape. On one side of the flowchannel, protrusions are cut out of the brass with a milling cutter, sothat shapes suitable for a locking mechanism are made. On the same sideof the flow channel as the protrusions, one or more circular holes aremade in the flow channel. The holes have an extended diameter on theouter side for o-rings. These one or more holes fit with circular shapeson the cup, so that a water tight sealing can be designed with the oneor more o-rings between the flow channel and the cup. In anotherpreferred embodiment, the media is gas, and the flow channel is made ofa polymeric material. In this case the holes and the protrusions arecreated at the time of casting of the flow channel.

Features 10 b, 13 are inside the flow channel. These are preferably madeby an insert 10 a, made of polymeric material reinforced with glassfibers. On the insert 10 a, metallic objects are optionally fixed forreflexion of the ultrasound or for redirection of the flow of the mediato be metered. The shape of the polymeric insert serves as reflectors 10b or redirectors in an especially advantageous embodiment. In someembodiments, some of the features such as reflectors 13 are fixed to thecup before it is mounted on the flow channel. In an especiallyadvantageous embodiment, an insert 10 a put into place from either theinlet or the outlet is fixed into place by the placement of the cup onthe flow channel. This is achieved by having features on the cup 13going into indents or holes on the insert.

Protrusions (11) on the cup serve as a part of the locking mechanism. Inan embodiment that needs maximum strength, it is an advantage to designthese protrusions as holes. In an embodiment with less constraints onstrength, it is an advantage to design the protrusions as incompleteholes, such as simple protrusions.

Protrusions (12) on the flow channel, serve as part of the lockingmechanism. In some embodiments it is an advantage to protect the lockingmechanism from tampering, and a hidden locking mechanism is preferred.This is designed by extending the protrusion on the flow channel or thecup over the locking mechanism, so that it cannot be seen or manipulatedfrom the outside.

Features (13) in the flow channel fixed to the cup.

Sealing means (14) can be located between the cup and the lid. In thepreferred embodiment, this sealing means consists of one or moreo-rings. Redundant o-rings will increase the robustness of the meter inthe case of imperfections on one of the parts involved in the sealingthat is the lid, the cup or an o-ring. The one or more o-rings is madeof a rubber-like or thermoplastic material.

Although the present invention has been described in connection withpreferred and advantageous embodiments, it is not intended to be limitedto the specified form and applications. Rather, the scope of the presentinvention is limited only by the accompanying claims.

In this section, certain specific details of the disclosed embodimentsare elaborated for purposes of explanation rather than limitation, so asto provide a clear and thorough understanding of the present invention.However, it should be understood readily by those skilled in this artthat the present invention may be applied in other embodiments which donot conform exactly to the details shown, without departingsignificantly from the spirit and scope of this disclosure. Further, inthis context, and for the purposes of brevity and clarity, detaileddescriptions of well-known apparatus, circuits and methodology have beenomitted so as to avoid unnecessary detail and possible confusion.

What is claimed is:
 1. An ultrasonic consumption meter comprising: aflow channel through which flows a media to be measured; two ultrasonictransducers that emit and receive ultrasound signals; an electroniccircuit that operates the meter; a single sealed housing enclosing thetransducers and the electronic circuit; the housing comprising a cup, alid and a seal; a locking mechanism that locks the housing in positionrelative to the flow channel said locking mechanism is positioned belowsaid lid; and wherein the flow channel has at least one hole for thehousing to contact with the media.
 2. The ultrasonic consumption meteraccording to claim 1, wherein an insert in the flow channel is fixed inits position by one or more features of the cup.
 3. The ultrasonicconsumption meter according to claim 1, wherein the flow channel has twoholes for the housing to contact with the media.
 4. The ultrasonicconsumption meter according to claim 3 wherein said housing cup contactsthe media.
 5. The ultrasonic consumption meter according to claim 2,wherein said insert is shaped to redirect the media flow inside the flowchannel where the media is being measured.
 6. The ultrasonic consumptionmeter according to claim 3 wherein an insert in the flow channel has twoholes that are aligned with said two holes in the flow channel thatpermit the housing cup to contact the media.
 7. The ultrasonicconsumption meter according to claim 3 wherein said ultrasound signalpasses through said housing twice during travel between said twotransducers.
 8. The ultrasonic consumption meter according to claim 5wherein said ultrasound signal passes through said two holes in theinsert and passes through said housing cup twice, during travel betweensaid two transducers.
 9. An ultrasonic consumption meter comprising: aflow channel through which flows a media to be measured; two ultrasonictransducers that emit and receive ultrasound signals; an electroniccircuit that operates the meter; a single sealed housing enclosing thetransducers and the electronic circuit; the housing comprising a cup, alid and a seal; a locking mechanism that locks the housing in positionrelative to the flow channel said locking mechanism is positioned belowsaid lid; said flow channel having two holes that permit the housing cupto contact the media; an insert in said flow channel, said insert shapedto redirect the media flow inside the flow channel where the media isbeing measured and having two holes that are aligned with said two holesin the flow channel; and wherein said ultrasound signal passes throughsaid two holes in the insert and passes through said housing cup twice,during travel between said two transducers.
 10. The ultrasonicconsumption meter according to claim 9 wherein said locking mechanism ispositioned entirely below said lid.
 11. The ultrasonic consumption meteraccording to claim 9 wherein said locking mechanism is positioned abovesaid flow channel.
 12. The ultrasonic consumption meter according toclaim 9 wherein said locking mechanism is positioned entirely below saidelectronic circuit.
 13. The ultrasonic consumption meter according toclaim 9 wherein said lid is not penetrated by electrical.
 14. Theultrasonic consumption meter according to claim 9 wherein said lockingmechanism does not contact said lid.
 15. An ultrasonic consumption metercomprising: a flow channel through which flows a media to be measured;two ultrasonic transducers that emit and receive ultrasound signals; anelectronic circuit that operates the meter; a single sealed housingenclosing the transducers and the electronic circuit; the housingcomprising a cup, a lid not penetrated by electrical wires, and a seal;a locking mechanism that locks the housing in position relative to theflow channel said locking mechanism is positioned below said lid, saidlocking mechanism being positioned above said flow channel, and entirelybelow said electronic circuit and said lid, and not contacting said lid;said flow channel having two holes that permit the housing cup tocontact the media; an insert in said flow channel, said insert shaped toredirect the media flow inside the flow channel where the media is beingmeasured and having two holes that are aligned with said two holes inthe flow channel; and wherein said ultrasound signal passes through saidtwo holes in the insert and passes through said housing cup twice,during travel between said two transducers.